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一种基于空间统计建模和特征重新校准的合成孔径雷达(SAR)场景分类深度学习新算法。

A New Deep Learning Algorithm for SAR Scene Classification Based on Spatial Statistical Modeling and Features Re-Calibration.

作者信息

Chen Lifu, Cui Xianliang, Li Zhenhong, Yuan Zhihui, Xing Jin, Xing Xuemin, Jia Zhiwei

机构信息

School of Electrical and Information Engineering, Changsha University of Science & Technology, Changsha 410114, China.

School of Engineering, Newcastle University, Newcastle upon Tyne NE1 7RU, UK.

出版信息

Sensors (Basel). 2019 May 30;19(11):2479. doi: 10.3390/s19112479.

DOI:10.3390/s19112479
PMID:31151259
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6604108/
Abstract

Synthetic Aperture Radar (SAR) scene classification is challenging but widely applied, in which deep learning can play a pivotal role because of its hierarchical feature learning ability. In the paper, we propose a new scene classification framework, named Feature Recalibration Network with Multi-scale Spatial Features (FRN-MSF), to achieve high accuracy in SAR-based scene classification. First, a Multi-Scale Omnidirectional Gaussian Derivative Filter (MSOGDF) is constructed. Then, Multi-scale Spatial Features (MSF) of SAR scenes are generated by weighting MSOGDF, a Gray Level Gradient Co-occurrence Matrix (GLGCM) and Gabor transformation. These features were processed by the Feature Recalibration Network (FRN) to learn high-level features. In the network, the Depthwise Separable Convolution (DSC), Squeeze-and-Excitation (SE) Block and Convolution Neural Network (CNN) are integrated. Finally, these learned features will be classified by the Softmax function. Eleven types of SAR scenes obtained from four systems combining different bands and resolutions were trained and tested, and a mean accuracy of 98.18% was obtained. To validate the generality of FRN-MSF, five types of SAR scenes sampled from two additional large-scale Gaofen-3 and TerraSAR-X images were evaluated for classification. The mean accuracy of the five types reached 94.56%; while the mean accuracy for the same five types of the former tested 11 types of scene was 96%. The high accuracy indicates that the FRN-MSF is promising for SAR scene classification without losing generality.

摘要

合成孔径雷达(SAR)场景分类具有挑战性但应用广泛,其中深度学习因其分层特征学习能力可发挥关键作用。在本文中,我们提出了一种新的场景分类框架,名为具有多尺度空间特征的特征重新校准网络(FRN-MSF),以在基于SAR的场景分类中实现高精度。首先,构建了一个多尺度全向高斯导数滤波器(MSOGDF)。然后,通过对MSOGDF、灰度梯度共生矩阵(GLGCM)和伽柏变换进行加权,生成SAR场景的多尺度空间特征(MSF)。这些特征由特征重新校准网络(FRN)进行处理以学习高级特征。在该网络中,集成了深度可分离卷积(DSC)、挤压激励(SE)模块和卷积神经网络(CNN)。最后,这些学习到的特征将通过Softmax函数进行分类。对从四个结合了不同波段和分辨率的系统中获得的11种SAR场景进行了训练和测试,获得了98.18%的平均准确率。为了验证FRN-MSF的通用性,对从另外两幅高分三号和TerraSAR-X大型图像中采样的5种SAR场景进行了分类评估。这5种类型的平均准确率达到了94.56%;而对相同的这5种类型在之前测试的11种场景上的平均准确率为96%。高准确率表明FRN-MSF在不失通用性的情况下对SAR场景分类具有前景。

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